/https://fbi.cults3d.com/uploaders/13773044/illustration-file/4bccf37e-3e82-43ac-815c-1ad129b46373/good_flat.jpg&w=828&h=828&output=webp&q=100&n=40 "Origami Bloom Pattern Foldable 3D Printer File Image 1")
/https://fbi.cults3d.com/uploaders/13773044/illustration-file/a8aee67a-c628-4cdf-8c78-1433af1d60ed/blooming-onion.gif&w=828&h=828&output=webp&q=100&n=40 "Origami Bloom Pattern Foldable 3D Printer File Image 2")
/https://fbi.cults3d.com/uploaders/13773044/illustration-file/21082bfd-49cb-40ec-a204-1b86890f4a5a/good_not_flat.jpg&w=828&h=828&output=webp&q=100&n=40 "Origami Bloom Pattern Foldable 3D Printer File Image 3")
/https://fbi.cults3d.com/uploaders/13773044/illustration-file/5cfc780e-72a0-4f0c-8f93-f95562ba2b33/Y6-2_Outreach_Printable.png&w=828&h=828&output=webp&q=100&n=40 "Origami Bloom Pattern Foldable 3D Printer File Image 4")
September 23, 2025
Description
This is a 3D-printable Yoshimura bloom pattern, specifically a Y-6.2 pattern (meaning it has six-fold symmetry and two rings extend out from the center). The membranes between the panels are designed to accommodate the folding process, and allow the model to rest in both the closed and the open states.
See this YouTube video by EzOrigami for instructions on how to fold your own: https://www.youtube.com/watch?v=u1D1XBx-kEw
BYU also made a video discussing the details of these patterns and their potential in engineering mechanisms and beyond: https://www.youtube.com/watch?v=YMV43l1nnoM
This model is best printed in PETG, or some other similarly flexible material (PLA also works fine). The model, at its current scaling, is intended to be printed with two 0.1mm layers as the base. This ensures that all folds have two overlapping layers of filament on which to bend (printing with a single 0.2mm thick bottom layer will mean that some of the hinges may break very easily). Here is a tutorial on how to modify individual layer heights in PrusaSlicer.
You're welcome to experiment with printing the first two layers out of a more flexible material, and then printing the remaining layers with something stiffer. PLA worked fine for the models we made on our own printers. See this post for a tutorial on how to make your own living hinges.
To read the backround research behind this work, visit: [https://doi.org/10.1098/rspa.2025.0299}(https://doi.org/10.1098/rspa.2025.0299)
Supplemental material can be found at ScholarsArchive: https://scholarsarchive.byu.edu/data/85/
This design was developed by the Compliant Mechanisms and Robotics Group (CMR) from Brigham Young University (BYU). Follow us at @byucmr on Instagram, @CompliantMechanismsResearchGroup on Facebook, or visit the BYU Compliant Mechanisms and Robotics website to learn more about compliant mechanisms.
The downloadable 3D print files provided here may be used, modified, and enjoyed for noncommercial use. To license developable mechanism technology for commercial applications, contact:
BYU Technology Transfer Office
3760 Harold B. Lee Library
Brigham Young University
Provo, UT 84602
Phone: (801) 422-6266
https://techtransfer.byu.edu/contact
License:
CC BY-NC - Attribution - Non commercial
byucmr
